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Dynamic Memory Management

Professor Jennifer Rexford

http://www.cs.princeton.edu/~jrex

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Goals of Today’s Lecture

• Dynamic memory management Garbage collection by the run-time system (Java) Manual deallocation by the programmer (C, C++)

• Challenges of manual deallocation Arbitrary request sizes in an arbitrary order Complex evolution of heap as a program runs

• Design decisions for the “K&R” implementation Circular linked-list of free blocks with a “first fit” allocation Coalescing of adjacent blocks to create larger blocks

3

Memory Layout: Heap

char* string = “hello”;int iSize;

char* f(){ char* p; scanf(“%d”, &iSize); p = malloc(iSize); return p;}

Text

BSS

Stack

Heap

Needed when required memory size is not known before the program runs

RoData

Data

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Allocating & Deallocating Memory

• Dynamically allocating memory Programmer explicitly requests space in memory Space is allocated dynamically on the heap E.g., using “malloc” in C, and “new” in Java

• Dynamically deallocating memory Must reclaim or recycle memory that is never used again To avoid (eventually) running out of memory

• “Garbage” Allocated block in heap that will not be accessed again Can be reclaimed for later use by the program

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Option #1: Garbage Collection

• Run-time system does garbage collection (Java) Automatically determines objects that can’t be accessed And then reclaims the resources used by these objects

Object x = new Foo();Object y = new Bar();x = new Quux();

if (x.check_something()) { x.do_something(y);}System.exit(0);

Object Foo() is never used

again!

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Challenges of Garbage Collection

• Detecting the garbage is not always easy “if (complex_function(y)) x = Quux();” Run-time system cannot collect all of the garbage

• Detecting the garbage introduces overhead Keeping track of references to objects (e.g., counter) Scanning through accessible objects to identify garbage Sometimes walking through a large amount of memory

• Cleaning the garbage leads to bursty delays E.g., periodic scans of the objects to hunt for garbage Leading to unpredictable “freeze” of the running program Very problematic for real-time applications … though good run-time systems avoid long freezes

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Option #2: Manual Deallocation

• Programmer deallocates the memory (C and C++) Manually determines which objects can’t be accessed And then explicitly returns the resources to the heap E.g., using “free” in C or “delete” in C++

• Advantages Lower overhead No unexpected “pauses” More efficient use of memory

• Disadvantages More complex for the programmer Subtle memory-related bugs Security vulnerabilities in the (buggy) code

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Manual Deallocation Can Lead to Bugs

• Dangling pointers Programmer frees a region of memory … but still has a pointer to it Dereferencing pointer reads or writes nonsense values

int main(void) { char *p; p = malloc(10); … free(p); … putchar(*p);}

May print nonsense character.

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Manual Deallocation Can Lead to Bugs

• Memory leak Programmer neglects to free unused region of memory So, the space can never be allocated again Eventually may consume all of the available memory

void f(void) { char *s; s = malloc(50); return;}

int main(void) { while (1) f(); return 0;}

Eventually, malloc()

returns NULL

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Manual Deallocation Can Lead to Bugs

• Double free Programmer mistakenly frees a region more than once Leading to corruption of the heap data structure … or premature destruction of a different object

int main(void) { char *p, *q; p = malloc(10); … free(p); q = malloc(10); free(p); …}

Might free the space allocated

to q!

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Challenges for Malloc and Free• Malloc() may ask for an arbitrary number of bytes

• Memory may be allocated & freed in different order

• Cannot reorder requests to improve performance

char *p1 = malloc(3);char *p2 = malloc(1);char *p3 = malloc(4);free(p2);char *p4 = malloc(6);free(p3);char *p5 = malloc(2);free(p1);free(p4);free(p5);

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Heap: Dynamic Memory

#include <stdlib.h>void *malloc(size_t size);void free(void *ptr);

0

0xffffffff

Stack

}Heap

Heap

char *p1 = malloc(3);char *p2 = malloc(1);char *p3 = malloc(4);free(p2);char *p4 = malloc(6);free(p3);char *p5 = malloc(2);free(p1);free(p4);free(p5);

p1

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Heap: Dynamic Memory

#include <stdlib.h>void *malloc(size_t size);void free(void *ptr);

0

0xffffffff

Stack

}Heap

Heap

char *p1 = malloc(3);char *p2 = malloc(1);char *p3 = malloc(4);free(p2);char *p4 = malloc(6);free(p3);char *p5 = malloc(2);free(p1);free(p4);free(p5);

p1

p2

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Heap: Dynamic Memory

#include <stdlib.h>void *malloc(size_t size);void free(void *ptr);

0

0xffffffff

Stack

}Heap

Heap

char *p1 = malloc(3);char *p2 = malloc(1);char *p3 = malloc(4);free(p2);char *p4 = malloc(6);free(p3);char *p5 = malloc(2);free(p1);free(p4);free(p5);

p1

p2p3

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Heap: Dynamic Memory

#include <stdlib.h>void *malloc(size_t size);void free(void *ptr);

0

0xffffffff

Stack

}Heap

Heap

char *p1 = malloc(3);char *p2 = malloc(1);char *p3 = malloc(4);free(p2);char *p4 = malloc(6);free(p3);char *p5 = malloc(2);free(p1);free(p4);free(p5);

p1

p2p3

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Heap: Dynamic Memory

#include <stdlib.h>void *malloc(size_t size);void free(void *ptr);

0

0xffffffff

Stack

}Heap

Heap

char *p1 = malloc(3);char *p2 = malloc(1);char *p3 = malloc(4);free(p2);char *p4 = malloc(6);free(p3);char *p5 = malloc(2);free(p1);free(p4);free(p5);

p1

p2p3

p4

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Heap: Dynamic Memory

#include <stdlib.h>void *malloc(size_t size);void free(void *ptr);

0

0xffffffff

Stack

}Heap

Heap

char *p1 = malloc(3);char *p2 = malloc(1);char *p3 = malloc(4);free(p2);char *p4 = malloc(6);free(p3);char *p5 = malloc(2);free(p1);free(p4);free(p5);

p1

p2p3

p4

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Heap: Dynamic Memory

#include <stdlib.h>void *malloc(size_t size);void free(void *ptr);

0

0xffffffff

Stack

}Heap

Heap

char *p1 = malloc(3);char *p2 = malloc(1);char *p3 = malloc(4);free(p2);char *p4 = malloc(6);free(p3);char *p5 = malloc(2);free(p1);free(p4);free(p5);

p1

p5, p2p3

p4

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Heap: Dynamic Memory

#include <stdlib.h>void *malloc(size_t size);void free(void *ptr);

0

0xffffffff

Stack

}Heap

Heap

char *p1 = malloc(3);char *p2 = malloc(1);char *p3 = malloc(4);free(p2);char *p4 = malloc(6);free(p3);char *p5 = malloc(2);free(p1);free(p4);free(p5);

p1

p5, p2p3

p4

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Heap: Dynamic Memory

#include <stdlib.h>void *malloc(size_t size);void free(void *ptr);

0

0xffffffff

Stack

}Heap

Heap

char *p1 = malloc(3);char *p2 = malloc(1);char *p3 = malloc(4);free(p2);char *p4 = malloc(6);free(p3);char *p5 = malloc(2);free(p1);free(p4);free(p5);

p1

p5, p2p3

p4

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Heap: Dynamic Memory

#include <stdlib.h>void *malloc(size_t size);void free(void *ptr);

0

0xffffffff

Stack

}Heap

Heap

char *p1 = malloc(3);char *p2 = malloc(1);char *p3 = malloc(4);free(p2);char *p4 = malloc(6);free(p3);char *p5 = malloc(2);free(p1);free(p4);free(p5);

p1

p5, p2p3

p4

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Goals for Malloc and Free

• Maximizing throughput Maximize number of requests completed per unit time Need both malloc() and free() to be fast

• Maximizing memory utilization Minimize the amount of wasted memory Need to minimize size of data structures

• Strawman #1: free() does nothing Good throughput, but poor memory utilization

• Strawman #2: malloc() finds the “best fit” Good memory utilization, but poor throughput

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Keeping Track of Free Blocks

• Maintain a collection of free blocks of memory Allocate memory from one of the blocks in the free list Deallocate memory by returning the block to the free list Ask the OS for additional block when more are needed

• Design questions How to keep track of the free blocks in memory? How to choose an appropriate free block to allocate? What to do with the left-over space in a free block? What to do with a block that has just been freed?

free free free

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Need to Minimize Fragmentation

• Internal fragmentation Allocated block is larger than malloc() requested E.g., malloc() imposes a minimum size (e.g., 64 bytes)

• External fragmentation Enough free memory exists, but no block is big enough E.g., malloc() asks for 128 contiguous bytes

64 64 64

33

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Simple “K&R-Like” Approach

• Memory allocated in multiples of a base size E.g., 16 bytes, 32 bytes, 48 bytes, …

• Linked list of free blocks Malloc() and free() walk through the list to allocate and deallocate

• Malloc() allocates the first big-enough block To avoid sequencing further through the list

• Malloc() splits the free block To allocate what is needed, and leave the rest available

• Linked list is circular To be able to continue where you left off

• Linked list in the order the blocks appear in memory To be able to “coalesce” neighboring free blocks

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Allocate Memory in Multiples of Base Size

• Allocate memory in multiples of a base size To avoid maintaining very tiny free blocks To align memory on size of largest data type (e.g., long)

• Requested size is “rounded up” Allocation in units of base_size Round:(nbytes + base_size – 1)/base_size

• Example: Suppose nbytes is 37 And base_size is 16 bytes Then (37 + 16 – 1)/16 is 52/16 which rounds down to 3

16 16 5

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Linked List of Free Blocks

• Linked list of free blocks

• Malloc() allocates a big-enough block

• Free() adds newly-freed block to the list

Allocated

Newlyfreed

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“First-Fit” Allocation

• Handling a request for memory (e.g., malloc) Find a free block that satisfies the request Must have a “size” that is big enough, or bigger

• Simplest approach: first fit Sequence through the linked list Stop upon encountering a “big enough” free block

• Example: request for 64 bytes First-fit algorithm stops at the 128-byte block

48 32 128 64 256

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Splitting an Oversized Free Block

• Simple case: perfect fit Malloc() asks for 128 bytes, and free block has 128 bytes Simply remove the free block from the list

• Complex case: splitting the block Malloc() asks for 64 bytes, and free block has 128 bytes

48 32 128 64 256

48 32 64 25664

64

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Circular Linked List of Free Blocks

• Advantages of making free list a circular list Any element in the list can be the beginning Don’t have to handle the “end” of the list as special

• Performance optimization Make the head be where last block was found More likely to find “big enough” blocks later in the list

48 32 64 25664

new head

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Maintaining Free Blocks in Order

• Keep list in order of increasing addresses Makes it easier to coalesce adjacent free blocks

• Though, makes calls to free() more expensive Need to insert the newly-freed block in the right place

Inuse

Inuse

Inuse

Free list

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Coalescing Adjacent Free Blocks

• When inserting a block in the free list “Look left” and “look right” for neighboring free blocks

Inuse

Inuse

Inuse

Inuse

Inuse

“Left” “Right”

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An Implementation Challenge

• Need information about each free block Starting address of the block of memory Length of the free block Pointer to the next block in the free list

• Where should this information be stored? Number of free blocks is not known in advance So, need to store the information on the heap

• But, wait, this code is what manages the heap!!! Can’t call malloc() to allocate storage for this information Can’t call free() to relinquish the storage, either

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Store Information in the Free Block

• Store the information directly in the free block Since the memory isn’t being used for anything anyway And allows data structure to grow and shrink as needed

• Every free block has a header Size of the free block Pointer to (i.e., address of) the next free block

• Challenge: programming outside the type system

size

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Conclusions

• Elegant simplicity of K&R malloc and free Simple header with pointer and size in each free block Simple circular linked list of free blocks Relatively small amount of code (~25 lines each)

• Limitations of K&R functions in terms of efficiency Malloc requires scanning the free list

– To find the first free block that is big enough Free requires scanning the free list

– To find the location to insert the to-be-freed block